KR102050194B1 - Injection molding machine - Google Patents

Abstract

The present invention relates to an injection molding machine capable of safely injecting an ingot into a melting furnace. The injection molding machine of the present invention comprises: a fixed mold (110) and an operating mold (120) to form a cavity when combining; a molten metal injection furnace (130) communicating with the cavity; a melting furnace (140) for supplying molten metal to the molten metal injection furnace; a plunger (150) for injecting the molten metal inside the molten metal injection furnace into the cavity; and an inclined plate (160) installed on an upper end of the melting furnace so as to allow the ingot (I) to be inclined to the inside of the melting furnace.

Description

Injection molding machine

The present invention relates to an injection molding machine capable of safely injecting an ingot into a melting furnace.

In general, injection molding is widely used in the manufacture of products of various shapes. In particular, injection molding is widely used in mass production of plastic or metal products having complicated shapes.

Conventional injection molding machines are fixed molds and movable molds to form a cavity at the time of molding, a molten metal injection passage communicating with the cavity, a melting furnace for supplying molten metal into the molten metal injection furnace, and the molten metal filled in the molten metal injection furnace It is composed of a plunger that is injected into the cavity.

In the conventional injection molding machine, when the plunger is advanced in the state where the stationary mold and the movable mold are combined, the molten metal is pushed into the plunger by the injection of the molten metal, and a certain amount is filled into the cavity.

However, such a conventional injection molding machine is very cumbersome because the operator has to periodically ingot the ingot (ingot) that is the raw material of the material into the furnace.

In addition, the operator has to inject the ingot directly into the furnace, but the molten metal of the furnace is splashed to the outside during the input process, so the risk of safety accidents is very high.

In addition, the conventional injection molding machine is subjected to a temperature shock to the molten metal of the melting furnace when the ingot below the reference temperature, such as winter, is introduced into the melting furnace, thereby producing quality problems such as bubbles or poor molding as the production conditions change. do.

KR 20-0215037 Y1

The present invention provides an injection molding machine that can safely supply an ingot to a melting furnace.

In addition, the present invention is to provide an injection molding machine that can always inject a reference temperature ingot irrespective of the external temperature so that a temperature shock does not occur in the molten metal.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the injection molding machine of the present invention is a stationary mold and a movable mold forming a cavity at the time of molding, a molten metal injection passage communicating with the cavity, a melting furnace for supplying a molten metal to the molten metal injection passage, and the molten metal injection And a plunger for injecting the molten metal inside the furnace into the cavity, and an inclined plate provided at an upper end of the melting furnace so that the ingot can be inclined into the melting furnace.

In addition, a first hinge coupling portion is formed on the inclined plate so that the inclined plate rotates to the outside of the melting furnace, and a second hinge coupling portion is formed at an upper end of the melting furnace to correspond to the first hinge coupling portion, and the first hinge coupling portion And the rotation axis may be fitted in the center of the second hinge coupler.

In this case, the inclination adjustment projection is formed radially along the outer surface of the first hinge coupling portion at a predetermined interval around the rotation axis to adjust the inclination of the inclination plate, the second hinge so as to be located between the inclination adjustment projections. Insertion hole is formed in the coupling portion, the fixing pin may be fitted to the insertion hole so as to interfere with the inclination adjustment projection.

In the present invention configured as described above, the ingot is slowly introduced into the interior of the melting furnace by the inclination plate installed at the top of the melting furnace, thereby preventing the safety accident in which the molten metal is splashed to the outside while being suddenly introduced into the melting furnace as in the prior art. It has an effect.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a schematic view showing the configuration of an injection molding machine according to an embodiment of the present invention;
Figure 2 is an exploded perspective view showing another embodiment of the inclined plate constituting the present invention, the inclined plate is rotatably installed;
3 is a state diagram used in the inclined plate of FIG.
4 is a further enlarged view illustrating a state in which an inclination of the inclination plate is configured to be adjusted as another embodiment of the inclination plate constituting the present invention;
Figure 5 is a front sectional view of the use state of the melting furnace showing a state in which the scale is formed on the inclined plate of the present invention.
Figure 6 is a cross-sectional view of the use state of the melting furnace showing a state in which the heating unit is provided on the inclined plate as another embodiment of the present invention;
7 is a side cross-sectional view of FIG. 6;
8 is a cross-sectional view of a state of use of a melting furnace showing a state where a cradle is provided as another embodiment of the present invention;
9 is a side view of FIG. 8.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of this embodiment, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted. First, with reference to the accompanying drawings will be described the configuration and operation according to a preferred embodiment of the present invention.

As shown in Figure 1, the injection molding machine according to an embodiment of the present invention is a fixed mold 110 and a movable mold 120 to form a cavity at the time of molding, and a molten metal injection passage 130 in communication with the cavity and It is basically provided with a melting furnace 140 for supplying the molten metal to the molten metal injection furnace 130, and the plunger 150 for injecting the molten metal inside the molten metal into the cavity.

Since the stationary mold 110 and the movable mold 120, the molten metal injection furnace 130, the melting furnace 140, and the plunger 150 are similar in their conventional construction and operation, detailed description thereof will be omitted. do.

According to the present invention, the inclined plate 160 is installed at the upper end of the melting furnace 140. The lower portion of the inclined plate 160 is located inside the melting furnace 140 to be immersed in the molten metal. Therefore, the inclined plate 160 should be made of a material that is heat resistant and very low in thermal conductivity, such as ceramics.

An ingot I introduced to the melting furnace 140 is placed on an upper surface of the inclined plate 160. The ingot I raised on the inclined plate 160 slowly moves downward by its own weight so that the lower part is submerged in the molten metal, and gradually moves downward into the molten metal as the melting proceeds.

Therefore, when the inclined plate 160 is provided, the ingot (I) is suddenly introduced into the melting furnace 140, thereby preventing safety accidents generated when the molten metal splashes to the outside.

On the other hand, as shown in Figure 2 and 3, the inclined plate 160 may be configured to be rotatable outside the melting furnace 140.

In this case, a first hinge coupling portion 161 is formed on the inclined plate 160, and a second hinge coupling portion 162 is formed on an upper end of the melting furnace 140 to correspond to the first hinge coupling portion 161. The rotation shaft 163 is fitted at the centers of the first hinge coupler 161 and the second hinge coupler 162.

Therefore, the operator can rotate the inclined plate 160 to the outside of the melting furnace 140 so as not to interfere with the operation when the inclined plate 160 is not used.

As shown in Figure 4, the inclined plate 160 is preferably configured to adjust the inclination.

In this case, the inclination adjustment protrusion 164 is radially formed along the outer surface of the first hinge coupling portion 161 at a predetermined interval around the rotation shaft 163, and is located between the inclination adjustment protrusions 164. An insertion hole 162a is formed in the second hinge coupling portion 162 so that the fixing pin 165 may be inserted into the insertion hole 162a so as to interfere with the inclination adjustment protrusion 164.

Therefore, when the worker rotates the inclined plate 160 to the desired inclination and passes through the fixing pin 165 between the inclined adjustment protrusions 164 and inserted into the insertion hole 162a, the inclined plate 160 is restricted while the inclined plate 160 is rotated. The inclination of is adjusted.

As such, the operator can appropriately adjust the feeding speed of the ingot (I) while changing the inclination of the inclined plate (160).

As shown in FIG. 5, a scale 166 may be displayed on an upper surface of the inclined plate 160. In this case, the operator can easily grasp the degree to which the ingot I has moved into the melting furnace 140 through the scale 166, so that the ingot I will not miss the additional timing.

An upper surface of the inclined plate 160 may further include a Zion pigment coating 167 that is discolored according to the temperature of the ingot I. When the Zion Pigment Coating unit 167 is provided, even when only the color of the Zion Pigment Coating unit 167 can be seen from a long distance, it is possible to easily determine the additional input time of the ingot I.

That is, when the heat of the molten metal is conducted along the ingot under the state in which the ingot I is dissolved and the overall temperature of the ingot I is increased, the Zion Pigment Coating part 167 is determined according to the temperature of the ingot I which is raised. When the color is changed, and the ingot (I) gradually falls out of the Zion Pigment Coating unit 167, the color of the Zion Pigment Coating unit 167 is returned to the original color, so that the operator may not see the scale 166 at a distance. Through the color of the Zion pigment coating 167 will be able to easily determine the addition time of the ingot (I).

On the other hand, the color of the upper surface of the inclined plate 160 may be formed in the same color as the color when the Zion pigment is discolored. In this case, since two colors are present on the inclined plate 160 only at the additional input time of the ingot I, the operator can more easily grasp the additional input time of the ingot I.

6 and 7, as another embodiment of the present invention, the inclined plate 160 may be further provided with a heating unit 170.

In this case, the heating unit 170 is fixed to the upper surface of the inclined plate 160, the cover 171, the top and the bottom is opened so that the ingot (I) passes through the inside, and the hot air supply pipe connected to the cover (171) ( 172 and a door 173 for opening and closing the open lower end of the cover 171. The door 173 is configured to receive opening and closing force through the driving device 174 installed on one side of the cover 171.

In addition, one side of the cover 171 is provided with a temperature sensor 175 for measuring the temperature inside the cover 171. When the temperature inside the cover 171 is sensed below the reference temperature through the temperature sensor 175, hot air supply is started. When the temperature inside the cover 171 is detected above the reference temperature, the hot air supply is stopped. The door 173 is automatically opened when hot air supply is stopped.

As such, when the heating unit 170 is provided, even if the temperature of the ingot I is lower than the reference temperature as in winter, the ingot I is always preheated to the reference temperature through the heating unit 170 before the melting furnace ( Since the ingot (I) below the reference temperature is introduced into the melting furnace 140, the temperature shock applied to the molten metal is not generated.

Therefore, even during the winter season, the production conditions are kept constant, and quality problems such as bubbles and molding defects do not occur.

As shown in Figure 8 and 9, as another embodiment of the present invention, both sides of the melting furnace 140, the elastic cradle 180 is installed, the inner side of the melting furnace 140, the elastic cradle 180 It is installed in the state floating in the melting furnace 140 through a) may be installed a mounting network 190 to elastically mount the ingot (I) descending on the inclined plate 160.

In this case, the mounting network 190 is a network-shaped mounting portion 191 is mounted on the ingot (I), and the support end extending from both sides of the mounting portion 191 penetrating both sides of the melting furnace 140 ( 192). In addition, through holes 141 penetrating the support end 192 are formed in a vertical long hole shape on both sides of the melting furnace 140.

The holding network 190 of such a configuration is lowered due to the weight of the ingot I while the ingot I is mounted, and the weight of the ingot I gradually decreases as melting of the ingot I proceeds. Ascending.

Therefore, the ingot I introduced into the melting furnace 140 is prevented from colliding with the bottom of the melting furnace 140 by the mounting network 190, thereby ensuring safer operation.

On the other hand, the limit switch 193 installed in the vertical direction on both sides of the melting furnace 140 may be further installed.

In this case, the contact end 194 is provided at the end of the elastic support 180 to be in contact with the limit switch 193 sequentially while rising by the weight of the ingot (I) which decreases as the ingot (I) is dissolved. Each limit switch 193 is provided with a lamp 195 which is turned on when the contact end 194 is in contact with the corresponding limit switch 193. The lamp 195 is preferably configured to be lit with light having different colors.

Accordingly, the operator can easily determine the melting progress state of the ingot I and the additional injection time of the ingot I through the number or color of the lamps 195 that are turned on.

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be construed as being included in the scope of the present invention.

110; Fixed mold 120; Movable mold
130; 140 molten metal injection furnace; Melting furnace
150; Plunger 160; Inclined plate
161; First hinge coupling portion 162; Second hinge coupling part
162a; Insertion hole 163; Axis of rotation
164; Tilt adjusting projection 165; Push pin

Claims (3)

A stationary mold and a movable mold forming a cavity at the time of molding, a molten metal injection passage communicating with the cavity, a melting furnace for supplying molten metal to the molten metal injection passage, and a plunger for injecting the molten metal inside the molten metal furnace into the cavity. And an inclined plate installed at an upper end of the melting furnace so that the ingot can be inclined into the melting furnace.
In order to rotate the inclined plate to the outside of the melting furnace, the first hinge coupling portion is formed on the inclined plate, and a second hinge coupling portion is formed at the upper end of the melting furnace to correspond to the first hinge coupling portion, the first hinge coupling portion and the second A rotating shaft is fitted in the center of the hinge coupler;
The scale is displayed on the upper surface of the inclined plate so as to determine the degree of movement of the ingot into the melting furnace;
An upper surface of the inclined plate is provided with a Zion pigment coating which is discolored according to the temperature of the ingot;
Both sides of the melting furnace is provided with an elastic cradle, and inside the melting furnace is provided with a mounting network installed in the state of floating in the melting furnace through the elastic cradle to elastically mount the ingot descending on the inclined plate and ;
The mounting network has a network-shaped mounting portion on which the ingot is mounted, and support ends extending from both sides of the mounting portion to penetrate both sides of the melting furnace;
Injection molding machine formed in the form of a vertical long hole through-hole penetrating the support end on both sides of the melting furnace. delete The method of claim 1,
To adjust the inclination of the inclined plate,
The inclination adjustment projection is formed radially along the outer surface of the first hinge coupling portion with a predetermined interval around the rotation axis,
Insertion holes are formed in the second hinge coupling portion to be located between the inclination adjusting protrusions,
An injection molding machine in which a fixing pin is inserted into the insertion hole so as to interfere with the tilt adjusting protrusion.

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